Variable voltage protection structures and method for making same

ABSTRACT

A variable voltage protection component in accordance with this invention comprises a reinforcing layer of insulating material having a substantially constant thickness embedded in a voltage variable material. With this configuration, the reinforcing layer defines a uniform thickness for the variable voltage protection component that is resist to compressive forces that may cause a reduction in the clamp voltage or a short in the voltage variable material. In addition, the variable voltage protection component can be attached to a compressible grounding plane to form a variable voltage protection device. Methods are provided for making the variable voltage protection component and device.

This application is a continuation, divisional, of application Ser. No.08/275,947, filed Jul. 14, 1994 now abandoned.

FIELD OF THE INVENTION

The present invention relates generally to variable voltage protectiondevices used to protect electronic circuits from overvoltage transientscaused by lightning, electromagnetic pulses, electrostatic discharges,ground loop induced transients, or inductive power surges. The presentinvention relates particularly to a variable voltage protectioncomponent with a substantially constant thickness for assembly in avariable voltage protection device.

BACKGROUND OF THE INVENTION

Voltage transients can induce very high currents and voltages that canpenetrate electrical devices and damage them, either causing hardwaredamage such as semiconductor burnout, or electronic upset such astransmission loss or loss of stored data. The voltage transients producelarge voltage spikes with high peak currents (i.e, over-voltage). Thethree basic over-voltage threats are electrostatic discharge, linetransients, and lightning. Electrostatic discharge typically occurs whenstatic charge dissipates off the body of a person in direct physicalcontact with an operating electronic system or integrated circuit chip.Line transients are surges in AC power lines. Line transients can alsooccur due to closing a switch or starting a motor. Lightning strikes canstrike stationary objects, such as a building, or mobile objects such asaircraft or missiles. Such strikes can suddenly overload a system'selectronics. At peak power, each of these threats is capable ofdestroying the sensitive structure of an integrated circuit chip.

Various overvoltage protection materials have been used previously.These materials are also known as nonlinear resistance materials and areherein referred to as voltage variable material. In operation, thevoltage variable material initially has high electrical resistance. Whenthe circuit experiences an overvoltage spike, the voltage variablematerial quickly changes to a low electrical resistance state in orderto short the overvoltage to a ground. After the overvoltage has passed,the material immediately reverts back to a high electrical resistancestate. The key operational parameters of the voltage variable materialare the response time, the clamp voltage, and the voltage peak. The timeit takes for the voltage variable material to switch from insulating toconducting is the response time. The voltage at which the voltagevariable material limits the voltage surge is called the clamp voltage.In other words, after the material switches to conducting, the materialensures that the integrated circuit chip, for example, will not besubjected to a voltage greater than the clamp voltage. The voltage atwhich the voltage variable material will switch (under surge conditions)from insulating to conducting is the switch voltage. These materialstypically comprise finely divided particles dispersed in an organicresin or insulating medium. For example, U.S. Pat. No. 4,977,357(Shlier) and U.S. Pat. No. 4,726,991 (Hyatt et al.) disclose suchmaterials.

Voltage variable materials and components containing voltage variablematerials have been incorporated into overvoltage protection devices ina number of ways. For example, U.S. Pat. Nos. 5,142,263 and 5,189,387(both issued to Childers et al.) disclose a surface mount device whichincludes a pair of conductive sheets and voltage variable materialdisposed between the pair of conductive sheets. U.S. Pat. No. 4,928,199(Diaz et al.) discloses an integrated circuit chip package whichcomprises a lead frame, an integrated circuit chip protected by anelectrode cover which is connected to ground on one side, and a variablevoltage switching device including the voltage variable materialconnected to the electrode cover on the other side. U.S. Pat. No.5,246,388 (Collins et al.) is directed to a device having a first set ofelectrical contacts that interconnect with signal contacts of anelectrical connector, a second set of contacts that connect to a ground,and a rigid plastic housing holding the first and second set of contactsso that there is a precise spacing gap to be filled with the overvoltagematerial. U.S. Pat. No. 5,248,517 (Shrier et al.) discloses painting orprinting the voltage variable material onto a substrate so thatconformal coating with voltage variable material of large areas andintricate surfaces can be achieved. By directly printing the voltagevariable material onto a substrate, the voltage variable materialfunctions as a discreet device or as part of the associated circuitry.

It is commonly known in the art that the thickness of the voltagevariable material and volume of the material are important toperformance. See U.S. Pat. No. 4,977,357 issued to Shrier, U.S. Pat. No.4,928,199 issued to Diaz et al. and U.S. Pat. No. 4,726,991 issued toHyatt et al. Likewise, it is known that the clamp voltage is reduced orthe voltage variable material can short out if put under pressure. SeeU.S. Pat. No. 5,248,517 issued to Shrier et al. Therefore, there hasbeen a long felt need in the art to accurately and cost-effectivelyproduce a variable voltage protection component having a uniformthickness of voltage variable material and to prevent shorts orvariations in the clamp voltage if pressure is applied to the material.In addition to these qualities, it is desirable to have the voltagevariable material be continuous across at least one ot the surfaces ofthe variable voltage protection component for universal application ofthe component, for example, across a single circuit line or multiplecircuit lines.

U.S. Pat. No. 5,262,754 (Collins) discloses an overvoltage protectionelement that can replace discrete devices presently used in protectingelectronic circuits. The overvoltage protection element includes a layerof insulating material having first and second spaced major surfacesspaced a predetermined distance to determine the thickness of theelement, a plurality of spaced holes extending between the majorsurfaces, and an overvoltage protection material contained within theholes formed in the layer of insulating material and extending betweenthe spaced major surfaces. The spaced holes are formed by perforatingthe layer of insulating material by mechanical punching, laserprocessing and cutting, chemical etching, etc. The holes are formed in apattern and should be wider than about one-half the width of theassociated electrical circuit to which the holes will overlay. Thespacing of the holes is determined by the spacing of the leads in theelectrical circuit.

The above U.S. Patents referred to are incorporated herein by reference.

Although the prior art discloses various materials and devices, there isa continuing and long felt need to provide improved cost-effectivevoltage variable materials and devices of more consistent performanceproperties to prevent variations in the clamp voltage under variousconditions in which the materials and devices are used.

SUMMARY OF THE INVENTION

The present invention provides a variable voltage protection componentfor use in a variable voltage protection device, more particularly avariable voltage protection component with an accurately controlleduniform thickness of voltage variable material that is resistant topressure applied to the component. The present invention also provides avariable voltage protection device comprising the variable voltageprotection component attached to a compressible conductive ground planethat is flexible so that the device will conform to irregular surfaces.

A variable voltage protection component in accordance with thisinvention comprises a reinforcing layer of insulating material having asubstantially constant thickness impregnated with a voltage variablematerial. With this configuration, the reinforcing layer defines auniform thickness for the variable voltage protection component that isresistant to compressive forces that may cause a reduction in the clampvoltage or a short in the voltage variable material. In addition, thevoltage variable material can be continuous across at least one surfaceof the variable voltage protection component for universal applicationto electronic circuits.

In accordance with one aspect of the present invention, a variablevoltage protection component for placement between a system ground andan electronic circuit is provided comprising a voltage variablematerial, and a reinforcing layer having a substantially constantthickness embedded in the variable voltage material.

In accordance with another aspect of the present invention, a variablevoltage protection component for placement between a system ground andan electronic circuit is provided comprising a reinforcing layer havinga substantially constant thickness, comprising a plurality of pieces ofinsulating material, said plurality of pieces defining a plurality ofvoids therebetween, and a voltage variable material impregnating thereinforcing layer and filling the plurality of voids.

In accordance with yet another aspect of the present invention, avariable voltage protection device for use in combination with a systemground is provided comprising a variable voltage protection component,and a compressible conductive ground plane contacting the variablevoltage protection component.

In one of its method aspects, a method for making a variable voltageprotection device is provided, comprising providing a variable voltageprotection material having a reinforcing layer of substantially constantthickness, providing a conductive substrate, depositing on theconductive substrate the variable voltage protection material containingthe reinforcing layer.

In another one of its method aspects, a method for making a variablevoltage protection device is provided comprising providing a conductivesubstrate having a reinforcing layer of substantially constant thicknesson a surface of the substrate and impregnating in the reinforcing layera variable voltage protection material.

In yet another one of its method aspects, a method of making a variablevoltage protection device is provided comprising providing acompressible conductive ground plane, providing a variable voltageprotection material, and depositing the variable voltage protectionmaterial on the compressible conductive ground plane.

BRIEF DESCRIPTION OF THE DRAWINGS

Many objects and advantages of the present invention will be apparent tothose of ordinary skill in the art when this specification is read inconjunction with the attached drawings. The invention will now bedescribed with reference to the accompanying drawings wherein likereference numerals are applied to like elements and wherein:

FIG. 1 is a partial cross-sectional perspective view of one embodimentof the variable voltage protection component with a center portionremoved to show the reinforcing layer is a woven glass mat;

FIG. 2 is a cross-sectional view of another embodiment of the presentinvention wherein the reinforcing layer is non-woven glass mat;

FIG. 3 is a cross-sectional view of another embodiment of the presentinvention mounted on a conductive ground plane wherein the reinforcinglayer is non-woven glass mat with spacers;

FIG. 4 is a cross-sectional view of yet another embodiment of thepresent invention wherein the reinforcing layer is sized spacers;

FIG. 5 is a cross-sectional view of the variable voltage protectioncomponent of FIG. 4 with smaller sized spacers;

FIG. 6 is a perspective view of an integrated circuit chip carrierutilizing the present invention;

FIG. 7 is a perspective view of a telephone connector utilizing thepresent invention;

FIG. 8 is a partial cross-sectional perspective view of the presentinvention installed on the edge of a printed circuit board;

FIG. 9 is a perspective view of a standard packaged variable voltageprotection device in accordance with the present invention;

FIG. 9A is a cross-sectional view of another embodiment of a standardpackaged variable voltage protection device in accordance with thepresent invention;

FIG. 10 is a perspective view of a lead frame for producing variablevoltage protection devices;

FIG. 11 is an integrated circuit chip lead frame with a variable voltageprotection component of the present invention installed;

FIG. 12 is a cross-sectional view of the chip lead frame of FIG. 11along line 12—12;

FIG. 13 is a discrete variable voltage protection component inaccordance with the present invention;

FIG. 14 is a cross-sectional view of a printed circuit board with thevariable voltage protection component of the present invention laminatedin the printed circuit board;

FIG. 15 is a cross-sectional view of another device utilizing thevariable voltage protection component of the present invention tocontact a predetermined pattern of leads;

FIG. 16 is a cross-sectional view of an integrated circuit chip leadframe with a variable voltage protection component of the presentinvention installed across a die pad ground;

FIG. 17 is a cross-sectional view of an alternate embodiment of aprinted circuit board utilizing the variable voltage protectioncomponent of the present invention; and

FIG. 18 is a cross-sectional view of another embodiment of an integratedcircuit chip lead frame with a variable voltage protection componentinstalled.

DETAILED DESCRIPTION OF THE INVENTION

In one embodiment of the present invention (FIG. 1), there is provided avariable voltage protection component 1 comprising a reinforcing layer 3embedded in the voltage variable material 5, or in other words thereinforcing layer is impregnated with the voltage variable material. Thereinforcing layer 3 has low compressibility and is selected to be ofpredetermined thickness so that the variable voltage protectioncomponent 1 will have a predetermined uniform thickness 7. By Using thereinforcing layer 3 to achieve a uniform thickness, repeatableelectrical performance can be achieved.

Preferably, the reinforcing layer 3 is a low compressibility fabricwhich has a low coefficient of thermal expansion and a low dielectricconstant. The reinforcing layer 3 can be any of a number of insulatingmaterials including, but not limited to, a porous polymer supportmaterial such as referred to in U.S. Pat. No. 4,950,546 (Dubrow et al.)and disclosed in U.S. patent application Ser. No. 711,119 filed Mar. 12,1985, (equivalent disclosure published as European Patent Application EP194872 on Sep. 17, 1986), porous synthetic resin polymer tape such asthat sold under the trademark “TEFLON” (manufactured by E. I. duPont deNemours & Co., Wilmington, Del.), polypropylene, glass, aromaticpolyamide such as that sold under the trademark “KEVLAR” (manufacturedby E. I. du Pont de Nemours & Co., Wilmington, Del.), polyester,thermoplastic polymer, thermosetting polymer, epoxy, and ceramic. Tiereinforcing layer 3 can be comprised of fibrous pieces of insulatingmaterial 9 forming a mat as shown in FIG. 1 or particulate pieces ofinsulating material 11 forming a non-woven mat as shown in FIG. 2. Thenon-woven mat can be comprised of random particulate pieces pressed orbonded together to form a sheet. The pieces can be pressed and alignedso as to be all substantially horizontal. Further, the non-woven mat canbe the woven fibers of the mat shown in FIG. 1 broken, cut or choppedinto smaller pieces. In addition, the fibers or pieces of insulatingmaterial can be coated with a metal coating provided that they aredistributed so as to not create a short or can be metal particles coatedwith insulating materials.

The reinforcing layer 3 includes a number of voids or spaces 13 betweenthe pieces 9 of insulating material in the mat (or pieces 11 in thenon-woven mat) comprising the reinforcing layer. In one embodiment, thevoltage variable material 5 impregnates the reinforcing layer 3 so thatthere is a continuous path 15 of voltage variable material from the topsurface 17 to the bottom surface 19 (FIG. 2). The reinforcing layer 3can be impregnated with the voltage variable material by a variety ofmethods as will be appreciated by one of ordinary skill in the art suchas: dipping the reinforcing layer in voltage variable material thensqueezing the reinforcing layer between two rollers; painting or pastingthe voltage variable material across the reinforcing layer; casting;calendaring; etc. There should be a sufficient amount of voltagevariable material 5 filling the voids 13 to carry voltage spikes orcurrent which occur in an overvoltage condition. The voltage variablematerial can be continuous across the top and bottom surface of thevariable voltage protection component so that the component can beuniversally used across variable lead patterns on a circuit withoutprecision tooling. Depending on the size of the conductive particles inthe voltage variable materials, a small number of conductive particlesor a large number may be present in the voids 13. For example, if theconductive particles are relatively large few particles will fit intothe voids therefore more will be on the top surface if the variablevoltage material is applied on only the top surface. In a like manner,more conductive particles will be on both the top and bottom surface ifthe variable voltage material is applied to both the top and bottomsurfaces. Whereas if the particles are relatively small more particleswill pass into the voids.

In another embodiment, the reinforcing layer 3 is embedded in thevoltage variable material 5. The reinforcing layer can be imbedded inthe voltage variable material by a variety of methods as will beappreciated by those of ordinary skill in the art such as coating asubstrate with the voltage variable material then laminating thereinforcing layer into the wet coating; preparing a layer of voltagevariable material then pressing the reinforcing layer into the voltagevariable material, etc.

The voltage variable characteristics of the variable voltage protectioncomponent 1 are determined by the voltage variable material used and thethickness of the component. The greater the thickness the higher theclamp voltage. If a clamp voltage between about 20 to 30 volts isdesired a typical thickness 7 for the variable voltage protectioncomponent would be 0.8 to 1.0 mils. If a clamp voltage between about 30to 40 volts is desired a typical thickness would be 1.0 to 2.0 mils. Ifa clamp voltage between 40 to 70 volts is desired a typical thicknesswould be 2.0 to 3.0 mils.

FIG. 3 illustrates that insulating spacers 21 such as ceramic or glassspheres can be added to the reinforcing layer 3 (mat or non-woven mat)to more accurately control the thickness 7. The spacers 21 extendbetween the top surface 17 and bottom surface 19. If a compressive forceis applied to the variable voltage protection component the spacers 21will act as supports and prevent the voltage variable material frombeing compressed, thus preventing shorts or reductions in the clampvoltage. In particular, the resistance to pressure is important duringprocessing at the curing temperature. The spacers 21 can be anypredetermined size as dictated by the characteristics (i.e., the clampvoltage, etc.) desired for the variable voltage protection component.For example, if a 1 mil thick variable voltage protection component isdesired then the spacers should be 0.9 to 1.1 mils, and preferably 1mil. In general, the spacers for most desirable voltage variableprotection components are between 0.2 to 10 mils in width. It iscontemplated that the spacers can be other shapes other than spherical.The size and shape of the spacers is also dependent on the size of themetal particles in the voltage variable material.

FIG. 3 further illustrates that the variable voltage protectioncomponent 1 can be attached to a conductive ground plane 23 to form avariable voltage protection device 25. The variable voltage protectioncomponent can be attached to the ground plane 23 by conductiveadhesives, conductive primers, non-conductive primers, direct bonding,etc. In addition, the variable voltage protection component 1 can beattached to the ground plane 23 by processes such as spraying, rolling,spin coating, laminating, molding or extruding. For example, theconductive ground plane 23 can be a predetermined length and thevariable voltage protection component 1 can be laminated to the groundplane 23 or the variable voltage protection component 1 and the groundplane 23 can be continuous reels and combined in an extrusion orlamination process.

The conductive ground plane 23 can be any of a variety of electricallyconductive materials known to one of ordinary skill in the art such ascopper, nickel plated copper, brass, beryllium copper, etc. Theconductive ground plane 23 can be flexible (such as a foil) so that itcan conform to irregular surfaces.

In yet another embodiment, the conductive ground plane 23 is preferablycompressible. With the compressible conductive ground plane 23, thevariable voltage protection device 25 can be placed or compressedbetween an electrical lead and a metal lead, such as an outer cover of aconnector without changing the thickness of the variable voltageprotection component 1 and thus preventing shorts and ensuring reliableelectrical characteristics and clamp voltage. The compressible groundplane 23 can be any of a variety of materials such as conductivepolymeric material, conductive silicon epoxy, cured conductive siliconerubber, conductive primers, etc. Preferably, the compressible groundplane is a conductive elastomer or conductive rubber. The compressibleconductive ground plane can be either electrically conductive at allvoltages or electrically conductive only at high voltages similar to thevoltage variable material.

In another embodiment, the conductive ground plane 23 has a compliantconsistency on at least one surface so that the variable voltageprotection device can conform to irregular surfaces. In addition, theconductive ground plane can have at least one adhesive surface so thatthe conductive ground plane will adhere to and maintain electricalcontact with an electrical component surface. Preferably, the adhesivesurface will have “quick stick” capability when it is pressed intoplace.

FIGS. 4 and 5 illustrate that the reinforcing layer 3 can be comprisedof spacers 21 only. In FIG. 4, the spacers 21 extend between the topsurface 17 and bottom surface 19 as discussed above to form areinforcing layer of desired thickness 7. The voltage variable material5 fills the voids 13 between the spacers to provided a continuous pathbetween the top and bottom surface. In FIG. 5, the spacers 21 act in thesame way but are smaller sized spheres which are stacked on top of oneanother to form the reinforcing layer of desired thickness 7. Thespacers 21 can be of any desired shape and size and stacked in as manylayers as desired to form the reinforcing layer.

The voltage variable material 5 used in accordance with the presentinvention can be any voltage variable material known in the art, forexample those disclosed in either U.S. Pat. No. 4,977,357 (Shrier) orU.S. Pat. No. 4,726,991 (Hyatt et al.), which are incorporated herein byreference. Generally, the voltage variable material comprises a binderand closely spaced conductive particles homogeneously distributed in thebinder and spaced to provide electrical conduction. In addition, variousmaterial such as that disclosed in U.S. Pat. No. 4,103,274 (Burgess etal.) can be used in accordance with the present invention.

Preferably, however, the voltage variable material 5 can be a voltagevariable thick film paste typically comprised of 50% solvent and 50%solids coating, the solid phase of which is comprised of 38% by weight(30% by volume) of conductors such as 10 micron aluminum, 3.5% by weight(3.4% by volume) silica coating for the conductors, and 58.5% by weight(66.6% by volume) of reinforced fluoro-silicone polymer whose dielectricbreakdown strength has been modified through the addition ofantioxidants and stabilizers such as specifically sized aluminum oxide.The size of the aluminum oxide can range from 0.01 to 5 microns. Thevoltage variable material can also be a solid which is laminated to thereinforcing mat. The voltage variable material can also be prepared asdisclosed in commonly assigned U.S. Pat. No. 5,807,509.

The variable voltage protection component 1 of the present invention canbe used in a variety of applications. For example, the variable voltageprotection component 1 can be used with a conductive ground plane 23 toform a variable voltage protection device 25 to be used in an integratedcircuit chip carrier 27 (FIG. 6). The integrated circuit Chip carrier 27contains integrated circuit chip 29. The conductive input/output pads(not shown) of chip 29 are typically wire bonded by wires 31 toconductive leads 33 in the chip carrier 27. The variable voltageprotection component 1 contacts the conductive leads 33 of the chipcarrier 27 and the Conductive ground plane 23 is typically grounded toone or several system grounds in the chip carrier 27 or any otherappropriate point in the chip package.

The variable voltage protection device 25 covers a portion of each ofthe conductive leads 33 of the chip carrier 27 leaving a portion of eachconductive lead 33 available for wire bonding of the chip 29 with wires31. In another embodiment, the conductive leads 33 can be wire bonded tothe chip 29 and the variable voltage protection device 25 is a lid thatcovers chip 29 and the conductive leads 33.

In one embodiment, the variable voltage protection device can be formedon the chip carrier 27 by first placing the variable voltage protectioncomponent 1 on the appropriate areas of the conductive leads 33 and thenattaching the conductive ground plane 23 to the variable voltageprotection component 1. Then connecting the conductive ground plane 23to a system ground in the chip carrier 27 or any other appropriate pointin the chip package, as discussed above. The variable voltage protectiondevice 25 in the chip carrier 27 allows all of the input/output leads tobe in contact with the variable voltage protection component 1 which isin turn in contact with the conductive ground plane 23. Therefore, anyovervoltage spikes which enter the package through any input/output leador conductive pace can immediately pass through the variable voltageprotection component 1 to the conductive ground plane 23. The variablevoltage protection component 1 can be connected to conductive leads 33by conductive adhesive or other appropriate means. In addition, thevariable voltage protection component can be stamped and heat laminateddirectly to the leads in a manner similar to tape automated bonding.

Another application of the variable voltage protection component 1 ofthe present invention is any of a variety of electrical connectors suchas RJ (i.e., telephone), coaxial, D-Sub (i.e., multiple pin computercable connectors), 38999 (i.e., aircraft), ARINC, SCSI (small computersystems interface), printed circuit board input/output connectors, chipsocket (pin grid arrays, PLCC), etc. The variable voltage protectioncomponent is essentially the same in all of the electrical connectorsexcept for the shape such as rectangular for D-Sub or circular for 38999connectors. In each connector the design will be the same in that therewill be a variable voltage protection component in electricalcommunication with a connector pin on one surface, and in contact with aground or a conductor that goes to system ground on another surface.Therefore, only the RJ connector will be described for illustrativepurposes.

The variable voltage protection component 1 can be used with conductiveground plane 23 to form a variable voltage protection device 25 to beused in an RJ electrical connector 35 (FIG. 7). The RJ electricalconnector 35 is comprised of insulating housing 37 having a matingconnector opening 39 for receiving a mating connector, Such as atelephone jack. The insulating housing 37 also has a variable voltageprotection device slot 41 for receiving the variable voltage protectiondevice 25. In the variable voltage protection device slot 41 is aplurality of electrical leads 43. The variable voltage protection device25 is placed in the variable voltage protection device slot 41 with thevariable voltage protection component 1 contacting the electrical leads43. Forward end 47 of electrical connector housing 45 is inserted inreceiving slot 49 and pushed forward until holising cover 51 is locatedover the variable voltage protection device 25 and guide 53 is fullyinserted in guide slot 55. The housing cover 51 can be biased in towardconductive ground plane 23 so that good electrical contact is made.Preferably, conductive ground plane 23 is compressible to preventpressure being transmitted to the overvoltage protection component 1,thus preventing shorts or variations in the clamp voltage. Anyovervoltage spikes which inter the electrical connector 35 through anyof the leads 43 can immediately pass through the variable voltageprotection component 1 to the conductive ground plane 23, then to theconnector housing 45 through housing cover 51 to be shunted off toground.

In another application, the variable voltage protection component 1 canbe used as webbing, tape, a label, or a film (FIG. 8) which can becustom cut to desired lengths for applying to uneven and irregularsurfaces, such as on printed circuit boards. The variable voltageprotection device comprised of the variable voltage protection component1 and conductive ground plane 23 can be adhered to a printed circuitboard 57 with adhesive tape 59. The variable voltage protectioncomponent 1 overlays any number of exposed printed circuit leads 61. Aground 63, such as a wire, conductive epoxy, solder, etc. is connectedfrom a designated ground lead on the printed circuit board to theconductive ground plane 23 through any of the openings 65 in theadhesive tape 59. The opening 65 can also be one continuous slot. Anovervoltage spike in any of the printed circuit leads can immediatelypass through the variable voltage protection component 1 to theconductive ground plane 23, then be shunted off to ground. In anotherembodiment, the variable voltage protection component adheres itself tothe printed circuit board, so that adhesive tape 59 can be omitted.

The variable voltage protection component can be put into standardpackaging components such as small outline, single-in-line packages, anddual-in-line packages for use in printed circuit boards. A small outlinepackage 67 (FIG. 9) is illustrative of each of the packaging styles. Thesmall outline package 67 is comprised of multiple pins 69 with thevariable voltage protection component 1 connecting each of the pins. Acommon conductive ground plane 23 contacts the variable voltageprotection component 1. A ground pin 71 is connected to conductiveground plane 23 by connection 73. Standard connecting techniques such aswire bonding, soldering, or conductive epoxy can be used for connection73. To protect the device a protective covering such as epoxy orstandard molding compound can be used to mold around the device to sealthe pin-variable voltage protection component-conductive ground planeinterfaces to protect the device.

The small outline package 67 is attached in parallel to a printedcircuit on a printed circuit boards to provide overvoltage protection tothe circuit. In the absence of an overvoltage situation, the smalloutline package 67 sits passively, not affecting the printed circuit.However, if an overvoltage is present the variable voltage protectioncomponent 1 conducts the spike to the system ground through theconductive ground plane 23 and ground pin 71.

FIG. 9A shows a device 68 similar to the small outline package 67, butcan be any standard packaging component as discussed above. The device68 is comprised of multiple input leads 70 on one side of the device andmultiple ground leads 72 opposite of the input leads 70. Variablevoltage protection component 1 connects the input leads 70 to the groundleads 72. A common conductive ground plane 23 contacts the variablevoltage protection component 1. As with the device shown in FIG. 9, thedevice 68 can be covered with a protective covering such as epoxy orstandard molding compound.

The device 68 is attached to a printed circuit in parallel the same asthe small outline package 67 discussed above. In the absence of anovervoltage situation, the device 68 sits passively. However, if anovervoltage is present in any of the input leads 70 the variable voltageprotection component 1 conducts the spike to the common c ground plane23 then to the system ground from the common ground plane 23 through anyor all of the ground leads 72.

As illustrated in FIG. 10, any of the packaged components can beproduced in a discrete, semis-atitomiiated or fully automated assemblyprocess using a discrete lead frame (typically about 7 inches in lengthwith 40 lead sets or die pads) or a continuous reel lead frame 73. Thelead frame acts as a conductive substrate. In one embodiment, the leadframe 73 has feed rails 75 with guide holes 77 for aligning and feedingthe lead frame through the manufacturing process. Other aligning andfeeding means, as are known by one of ordinary skill in the art, can beused such as stationary guide rails abutting the side of the feed rails75 and friction wheels pulling or pushing the lead frames through theprocess.

In one embodiment, the variable voltage protection component 1 isdeposited on the lead frame 75. A thin insulating primer can be appliedto the lead frame to help the variable voltage protection componentadhere to the lead frame, or the variable voltage protection componentcan be bonded to the lead frame by lamination, conductive adhesives,conductive epoxy, pressure, temperature, spraying, rolling, spincoating, molding, extruding, etc. Then the conductive ground plane 23 isattached to the variable voltage protection component 1. Each of theground pins 71 is then attached to the conductive ground plane 23 byconnection 73. For making device 68, the ground leads are not attachedto the ground plane 23. After packaging, each of the lead sets 81 arediced out of the lead frame 75 for forming into the standard packagesillustrated in FIGS. 9 and 9A. The lead frame 75 shown in FIG. 10 haseight leads per lead set 81, however, the lead frame can have any numberof desired leads.

It is contemplated that the steps just described can be done indiffering order, such as the variable voltage protection component 1 canbe applied to the conductive ground plane 23 and die stamped-out beforebeing attached to the lead sets (or die pads) 81. Or the conductiveground plane 23 can be connected to the ground pin 71 after the leadsets have been diced from the lead frame 75.

In another embodiment, the method of making the packaged devices can bea fully automated process, such as a spraying, rolling, laminating, orextruding process, in which the lead frames are continuous with multiplelead frame pins 69 perpendicular to the feed rails 77 and the variablevoltage protection component 1 is applied to the lead frames. Forexample, the variable voltage protection component 1 and conductiveground plane 23 can be in continuous tapes that are laminated to thecontinuous lead frames. Then the assembled components can be dividedinto a predetermined number of leads. For the device illustrated in FIG.9, one lead can be selected as the ground pin and connected to theconductive ground plane.

In other embodiments, the lead frame 75 can be a conductive substratehaving a predetermined pattern matching the leads on a printed circuitboard or the conductive substrate can be a continuous sheet that isphoto-etched to form a predetermined pattern to match the leads on aprinted circuit board or an integrated circuit. Then the photo-etchedareas are filled with voltage variable material.

FIG. 11 shows another application of the present invention, wherein thevariable voltage protection device 25 can be used in tape form on anintegrated circuit chip lead frame 83. The integrated circuit chip leadframe has a plurality of leads 85 connected to an integrated circuitchip 29 and for connecting to a printed circuit board or multiple chipmodule. As can be seen in FIG. 12, the variable voltage protectiondevice 25, comprising variable voltage protection component 1 andconductive ground plane 23, is “taped” across the plurality of leads 85.The leads 85 are connected to the chip 29 by wires 31. Each strip ofconductive ground plane 23 can be attached to a system ground when theintegrated circuit chip lead frame 83 is attached to a printed circuitboard or multiple chip module.

In another embodiment utilizing the integrated circuit chip lead frame83, the variable voltage protection component can be applied across theleads 85 and die pad ground 109 on the bottom of the integrated circuitchip lead frame 83 (FIG. 16). The die pad ground 109 is connected tosystem ground when the integrated circuit chip lead frame 83 is attachedto a printed circuit board or multiple chip module. In this way, whenone of leads 85 experiences a voltage spike, the variable voltageprotection component 1 conducts the spike laterally through the variablevoltage protection component to the die pad ground 109 to protect chip29. Optionally, ground plane 23 can be added for better performance bythe variable voltage protection device. With the ground plane 23attached, when one of leads 85 experiences a voltage spike, the variablevoltage protection component 1 conducts the spike to ground plane 23then to the die pad ground 109.

In yet another embodiment utilizing an integrated circuit chip leadframe wire bonded by wires 31 to chip 29, the variable voltageprotection component can be applied between the leads 85 and die padground 109 (FIG.18). The die pad ground 109 is connected to systemground when the integrated circuit chip lead frame is attached to aprinted circuit board or multiple chips module. When any of the leads 85experiences a voltage spike, the variable voltage protection component 1conducts the spike to the system ground through die pad ground 109.

A discrete surface moLIult device 87 is shown in FIG. 13. The device 87comprises a composite of variable voltage protection component 1sandwiched between two conductive ground planes 23, and two outerconductive layers 89 for surface mounting the device 87. The layers ofthe composite can be assembled using a laminating or coating process. Aprotective coating of epoxy can be applied (such as by painting) to thedevice 87 to protect the variable voltage protection component 1.

In FIG. 14, the variable voltage protection device 25 is laminated intoa printed circuit board 91 having signal leads 93. The variable voltageprotection component 1 is applied to or around the signal leads 93.Layers 95 on either side of the variable voltage protection device 25and signal leads 93 make up the printed circuit board. The conductiveground plane 23 is attached to a system ground. If a signal leadexperiences an overvoltage situation, the variable voltage protectioncomponent 1 conducts the spike to the conductive ground plane 23 whichShIlnlts it off to the system ground.

In another embodiment, the variable voltage protection component 1 canbe utilized in a printed circuit board 91 using the vias orthrough-holes 111 in the printed circuit board (FIG. 17). The vias 111can be lined with variable voltage protection component 1 that contactsa ground plane 23, and the signal leads 93 in the printed circuit board.It is important that the ground plane 23 terminates at the variablevoltage protection component 1. It is also important that the signalleads 93 extend through the variable voltage protection component 1 tocontact a layer of conductive material 113, such as solder, whichoverlays the variable voltage protection component 1. In this way, whena pin (not shown) is inserted in via 111 the pin is in electricalcommunication with signal lead 93. If signal lead 93 experiences anovervoltage situation, the variable voltage protection component 1conducts the spike to ground plane 23 which shunts the spike off tosystem ground.

FIG. 15 shows a device 97 utilizing the variable voltage protectioncomponent 1 to contact a predetermined pattern of signal leads 99 andground leads 101. A conductive strip 103 has a pattern of conductivebumps 105, which are etched, stamped or machined to match apredetermined pattern of ground leads 101. The variable voltageprotection component 1 is placed between the conductive bumps 105 isflattened off to be even with the conductive bumps 105. A layer 107 ofconductive material, such as conductive epoxy or conductive adhesive, isapplied to the conductive bumps 105 and variable voltage protectioncomponent 1 to match the predetermined pattern of signal leads 99 andground leads 101 When one of the signal leads 99 experiences anovervoltage spike, the variable voltage protection component conductsthe spike to the conductive strip 103. Then the spike is conductedthrough the layer 107 of conductive material to the ground leads 101. Inaddition, layer 107 of the device 97 can be omitted and the variablevoltage protection component 1 can be adhered directly to the leads.

The foregoing has described the principles, preferred embodiments andmodes of operation of the present invention. However, the inventionshould not be construed as being limited to the particular embodimentsdiscussed. Thus, the above-described embodiments should be regarded asillustrative rather than restrictive, and it should be appreciated thatvariations may be made in those embodiments by workers skilled in theart without departing from the scope of the present invention asdeficient by the following claims.

What is claimed is:
 1. A variable voltage protection component forplacement between a ground and an electronic circuit comprising: avoltage variable material; a reinforcing layer having a substantiallyconstant thickness embedded in the voltage variable material; and acompressible conductive ground plane contacting said variable voltageprotection component.
 2. The variable voltage protection component ofclaim 1 further comprising an electrical connector having at least onelead and a ground; said voltage variable material contacting said atleast one lead and said compressible conductive ground plane being inelectrical communication with said ground.
 3. The variable voltageprotection component of claim 2 wherein the electrical connectorcomprises an RJ connector, a coaxial connector, a D-Sub connector, a38999 aircraft connector, a ARINC connector, a SCSI connector, a printedcircuit board input/output connector, or a chip socket.
 4. A variablevoltage protection component for placement between a ground and anelectronic circuit comprising: a voltage variable material; areinforcing layer having a substantially constant thickness embedded inthe voltage variable material; a conductive ground plane contacting thevariable voltage protection component; and a packaging component for useon a printed circuit board having at least one first lead spaced from atleast one second lead; said voltage variable material connecting saidfirst lead to said second lead and being in electrical communicationwith said conductive ground plane.
 5. The variable voltage protectioncomponent of claim 4 wherein the packaging component comprises a smalloutline package, a single in line package, or a dual in line package.6.A variable voltage protection component for placement between a groundand an electronic circuit comprising: a voltage variable material; areinforcing layer having a substantially constant thickness embedded inthe voltage variable material; a conductive ground plane contacting thevariable voltage protection component; and a lead frame having aplurality of signal leads and a ground lead; said voltage variablematerial contacting said plurality of signal leads and said ground leadbeing in electrical communication with said conductive ground plane ofsaid variable voltage protection component.
 7. A variable voltageprotection device for use in combination with a ground comprising: avariable voltage protection component; and a compressible conductiveground plane contacting the variable voltage protection component. 8.The variable voltage protection device of claim 7 wherein the variablevoltage protection component comprises: a voltage variable material; anda reinforcing layer having a substantially constant thickness embeddedin the variable voltage material.
 9. The variable voltage protectiondevice of claim 7 further comprising an electrical connector having atleast one lead and a ground; said voltage variable material contactingsaid at least one lead and said conductive ground plane being inelectrical communication with said ground.